Paul-Drude-Institut für Festkörperelektronik (PDI) - Control of Elementary Excitations by Acoustic Fields
PDI is a research institute in Berlin, Germany. We perform basic and applied research at the nexus of materials science, condensed matter physics, and device engineering.
Acoustic modulation of quantum dots in microcavities for GHz-rate single photon
sources and optomechanics
Master Thesis Topic
Tasks:
III-V semiconductor quantum dots (QDs) are the purest single photon sources at cryogenic
temperatures. Their emission rate and directionality can be improved by placing them in a
photonic environment such as a microcavity (MC) and taking advantage of the Purcell effect.
However, the matching of the QD energy with that of the MC is challenging, especially for high-Q
MCs. Another challenge is the requirement for the resonant excitation to achieve narrowest
linewidth and highest single-photon purity.
The key ideas of the project are to place InAs or GaAs QDs in hybrid Q > 10000 microcavities
and use GHz-frequency piezoelectrically excited bulk acoustic waves to realize dynamic Purcell
effect. By further shallow patterning of the microcavity we can introduce confined photonic modes
with well-defined energies. In this case, we envision that the acoustic modulation of the QD energy
will lead to multiple dynamics resonances. Our ultimate goal is to demonstrate on-chip single
photon sources triggered at GHz rates as well as new optomechanical devices for microwave-to-
optical conversion.
Objective:
The main objective of the project is to demonstrate dynamic Purcell effect and GHz-triggered
single photon emission in patterned MCs with III-V QDs. You will be working on the following
tasks:
- Needle in a haystack. Using cryogenic photoluminescence, you will identify photonic
structures that contain single QDs. - Shock to the system. Apply the acoustic wave to demonstrate QD energy and intensity
modulation. Tune the acoustic amplitude to observe multiple resonances between QD and
confined photonic modes. - Quantum light. With the help of correlation measurements, you will demonstrate single
photon emission at GHz frequencies.
Methodology:
You will use cryogenic (liquid-He) photoluminescence with non-resonant and resonant optical
excitation to measure QD emission. Using a radio-frequency generator, you will excite acoustic
transducers to generate an acoustic wave and detect dynamic changes in the QD emission
energy and intensity. You will learn to measure second-order auto-correlation to study single
photon emission from the device.
Expected Outcomes
- Realization of dynamic Purcell control of single photon emission at GHz frequencies
- Demonstration of a novel platform for quantum technologies and getting an invaluable
experience along the way.
Requirements:
Skills and Requirements
- Curiosity
- Base knowledge of semiconductor physics and materials
What we offer:
Opportunities and Benefits
- Modern labs with a wide range of experimental techniques.
- Supportive environment with experts for various scientific sub-fields.
- International and culturally diverse community.
- Location in the heart of Berlin with excellent public transport connections.
- Subsidized travel ticket.
How to apply:
Dr. Alexander Kuznetsov
+49 30 20377-430
kuznetsov@pdi-berlin.de
Facts
ID: 201909
- Num. of employees:
- 100
- Site:
-
- Mitte, Berlin (Germany)
- Type:
- Thesis
- Part-/Full-time:
- Full-time
- Starting date (earliest):
- At the earliest possible
- Remuneration:
- 13,90€/hour
- Remote work:
- Not possible
- Scope:
- Natural sciences
- Physics
- Research
- Field of studies:
- Natural sciences and mathematics
- Materials science
- Physics
- Level of education:
- BSc
- Working language and expected level:
-
- German (Fluent in speech and writing)
- English (Fluent in speech and writing)
Actions
Apply
- Closing date:
- 26/03/26
- Subject:
- Master Theis Topic
- By email:
- kuznetsov@pdi-berlin.de
Contact
- Contact person:
- Erika Szegedy
- Contact email:
- szegedy@pdi-berlin.de